Litcius/Paper detail

Device-independent randomness based on a tight upper bound of the maximal quantum value of chained inequality

Youwang Xiao, Xinhui Li, Jing Wang, Ming Li, Shao-Ming Fei

2023Physical review. A/Physical review, A13 citationsDOIOpen Access PDF

Abstract

The violation of the Bell inequality not only provides the most radical departure of quantum theory from classical concepts, but also paves the way for applications such as device-independent randomness certification. Here, we derive the tight upper bound of the maximum quantum value for the chained Bell inequality with an arbitrary number of measurements on each party. The constraints where the upper bound saturates are also presented. This method provides us the necessary and sufficient conditions for some quantum states to violate the chained Bell inequality with an arbitrary number of measurements. Based on the tight upper bound we present the lower bounds on the device-independent randomness with respect to the Werner states. In particular, we present lower bounds on the randomness generation rates of the chained Bell inequality for a different number of measurements, which are compared with the family of Bell inequalities proposed by Wooltorton et al. [Phys. Rev. Lett. 129, 150403 (2022)]. Our results show that the chained Bell inequality with three measurements has certain advantages at a low level of noise and could be used to improve randomness generation rates in practice.

Topics & Concepts

RandomnessUpper and lower boundsBell's theoremMathematicsCHSH inequalityQuantumValue (mathematics)InequalityStatistical physicsQuantum mechanicsPhysicsQuantum entanglementMathematical analysisStatisticsQuantum Mechanics and ApplicationsQuantum Information and CryptographyQuantum Computing Algorithms and Architecture